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Chapter 9 TRAP Routines and Subroutines

Chapter 9 TRAP Routines and Subroutines. System Calls. Certain operations require specialized knowledge and protection : specific knowledge of I/O device registers and the sequence of operations needed to use them

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Chapter 9 TRAP Routines and Subroutines

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  1. Chapter 9TRAP Routines andSubroutines

  2. System Calls • Certain operations require specialized knowledgeand protection: • specific knowledge of I/O device registersand the sequence of operations needed to use them • I/O resources shared among multiple users/programs;a mistake could affect lots of other users! • Not every programmer knows (or wants to know)the level of detail required • Solution: Provide service routinesorsystem calls • OS code to perform low-level operations

  3. System Call • 1. User program invokes system call. • 2. Operating system code performs operation. • 3. Returns control to user program. In LC-3, this is done through theTRAP mechanism.

  4. LC-3 TRAP Mechanism • 1. A set of service routines. • part of operating system -- routines start at arbitrary addresses(convention is that system code is below x3000) • up to 256 routines • 2. Table of starting addresses – Trap Vector Table. • stored at x0000 through x00FF in memory • called System Control Block in some architectures • 3. TRAP instruction. • used by program to transfer control to operating system • 8-bit trap vector names one of the 256 service routines • 4. A linkage back to the user program. • want execution to resume immediately after the TRAP instruction

  5. TRAP Instruction • Trap vector • identifies which system call to invoke • 8-bit index into table of service routine addresses • in LC-3, this table is stored in memory at 0x0000 – 0x00FF • 8-bit trap vector is zero-extended into 16-bit memory address • Where to go • lookup starting address from table; place in PC • How to get back • save address of next instruction (current PC) in R7

  6. TRAP NOTE: PC has already been incrementedduring instruction fetch phase.

  7. RET (JMP R7) • How do we transfer control back toinstruction following the TRAP? • We saved old PC in R7. • JMP R7 gets us back to the user program at the right spot. • LC-3 assembly language lets us use RET (return)in place of “JMP R7”. • Must make sure that service routine does not change R7, or we won’t know where to return.

  8. TRAP Mechanism Operation • Lookup starting address. • Transfer to service routine. • Return (JMP R7).

  9. Example: Using the TRAP Instruction • .ORIG x3000 • LD R2, TERM ; Load negative ASCII ‘7’ LD R3, ASCII ; Load ASCII differenceAGAIN TRAP x23 ; input character ADD R1, R2, R0 ; Test for terminate BRz EXIT ; Exit if done ADD R0, R0, R3 ; Change to lowercaseTRAP x21 ; Output to monitor... BRnzp AGAIN ; ... again and again...TERM .FILL xFFC9 ; -‘7’ASCII .FILL x0020 ; lowercase bitEXIT TRAP x25 ; halt.END

  10. Example: Output Service Routine • .ORIG x0430 ; syscall address • ST R1, SaveR1 ; save R1; ----- Write characterTryWrite LDI R1, DSR ; get status BRzp TryWrite ; look for bit 15 onWriteIt STI R0, DDR ; write char; ----- Return from TRAPReturn LD R1, SaveR1 ; restore R1RET ; back to user • CRTSR .FILL xFE04CRTDR .FILL xFE06SaveR1 .FILL 0 .END stored in table,location x21

  11. TRAP Routines and their Assembler Names

  12. Saving and Restoring Registers • Must save the value of a register if: • Its value will be destroyed by service routine, and • We will need to use the value after that action. • Who saves? • caller of service routine? • knows what it needs later, but may not know what gets altered by called routine • called service routine? • knows what it alters, but does not know what will be needed later by calling routine

  13. Example • LEA R3, Binary LD R6, ASCII ; char->digit template LD R7, COUNT ; initialize to 10AGAIN TRAP x20 ; Get char ADD R0, R0, R6 ; convert to number STR R0, R3, #0 ; store number ADD R3, R3, #1 ; incr pointer ADD R7, R7, -1 ; decr counter BRp AGAIN ; more? BRnzp NEXTASCII .FILL xFFD0COUNT .FILL #10Binary .BLKW #10 What’s wrong with this routine?

  14. Saving and Restoring Registers • Called routine -- “callee-save” • Before start, save any registers that will be altered(unless altered value is desired by calling program!) • Ex: R0 in call to GETC • Before return, restore those same registers • Calling routine -- “caller-save” • Save registers destroyed by own instructions orby called routines (if known), if values needed later • save R7 before TRAP • save R0 before TRAP x20 (get character) • Or avoid using those registers altogether • Values are saved by storing them in memory.

  15. Question • Can a service routine call another service routine? • If so, is there anything special the calling service routinemust do?

  16. What about User Code? • Service routines provide three main functions: • 1. Shield programmers from system-specific details. • 2. Write frequently-used code just once. • 3. Protect system resources from malicious/clumsy programmers. • Useful for user code too!

  17. Subroutines • A subroutine is a program fragment that: • lives in user space • performs a well-defined task • is invoked (called) by another user program • returns control to the calling program when finished • Like a service routine, but not part of the OS • not concerned with protecting hardware resources • no special privilege required • Reasons for subroutines: • reuse useful (and debugged!) code • divide task among multiple programmers • use vendor-supplied library of useful routines

  18. JSR Instruction • Jumps to a location (like a branch but unconditional),and saves current PC (addr of next instruction) in R7. • saving the return address is called “linking” • target address is PC-relative (PC + Sext(IR[10:0])) • bit 11 specifies addressing mode • if =1, PC-relative: target address = PC + Sext(IR[10:0]) • if =0, register: target address = contents of register IR[8:6]

  19. JSR NOTE: PC has already been incrementedduring instruction fetch stage.

  20. JSRR Instruction • Just like JSR, except Register addressing mode. • target address is Base Register • bit 11 specifies addressing mode • What can a JSRR do that a JSR cannot?

  21. JSRR NOTE: PC has already been incrementedduring instruction fetch stage.

  22. Returning from a Subroutine • RET (JMP R7) gets us back to the calling routine. • just like TRAP

  23. Example: Negate the value in R0 • 2sComp NOT R0, R0 ; flip bits ADD R0, R0, #1 ; add one RET ; return to caller • To call from a program (within 1024 instructions): • ; need to compute R4 = R1 - R3 ADD R0, R3, #0 ; copy R3 to R0JSR 2sComp ; negate ADD R4, R1, R0 ; add to R1 …

  24. Passing Information to/from Subroutines • Arguments • A value passed in to a subroutine is called an argument. • This is a value needed by the subroutine to do its job. • Examples: • In 2sComp routine, R0 is the number to be negated • In OUT service routine, R0 is the character to be printed. • In PUTS routine, R0 is address of string to be printed. • Return Values • A value passed out of a subroutine is called a return value. • This is a value that you called the subroutine to compute. • Examples: • In 2sComp routine, negated value is returned in R0. • In GETC service routine, character read from the keyboardis returned in R0.

  25. Using Subroutines • In order to use a subroutine, a programmer must know: • its address (or at least a label that will be bound to its address) • its function (what does it do?) • NOTE: The programmer does not need to knowhow the subroutine works, butwhat changes are visible in the machine’s stateafter the routine has run. • its arguments (where to pass data in, if any) • its return values (where to get computed data, if any)

  26. Saving and Restore Registers • Since subroutines are just like service routines,we also need to save and restore registers, if needed. • Generally use “callee-save” strategy,except for return values. • Save anything that the subroutine will alter internallythat shouldn’t be visible when the subroutine returns. • It’s good practice to restore incoming arguments to their original values (unless overwritten by return value). • Save at beginning, restore at end • Remember: You MUST save R7 if you call any othersubroutine or service routine (TRAP). • Otherwise, you won’t be able to return to caller.

  27. Example • Write a subroutine FirstChar to: find the first occurrenceof a particular character (in R0) in a string (pointed to by R1); return pointer to character or to end of string (NULL) in R2. • (2) Use FirstChar to write CountChar, which: counts the number of occurrences of a particular character (in R0) in a string (pointed to by R1);return count in R2. • Can write the second subroutine first, without knowing the implementation of FirstChar!

  28. CountChar Algorithm (using FirstChar) save regs R4 <- 0 R1 <- R2 + 1 R4 <- R4 + 1 call FirstChar save R7,since we’re using JSR R3 <- M(R2) R2 <- R4 restore regs R3=0 no return yes

  29. CountChar Implementation • ; CountChar: subroutine to count occurrences of a charCountChar You Write!

  30. R3=R0 save regs yes R2 <- R1 no R2 <- R2 + 1 R3 <- M(R2) restore regs R3=0 no return yes FirstChar Algorithm

  31. FirstChar Implementation • ; FirstChar: subroutine to find first occurrence of a charFirstChar You Write!

  32. Library Routines • Vendor may provide object files containinguseful subroutines • don’t want to provide source code -- intellectual property • assembler/linker must support EXTERNAL symbols(or starting address of routine must be supplied to user) • ... .EXTERNAL SQRT • ... LD R2, SQAddr ; load SQRT addr JSRR R2 ...SQAddr .FILL SQRT • Using JSRR, because we don’t know whether SQRTis within 1024 instructions.

  33. Lab 4 • .EXTERNAL keyword not supported by assembler  • You can use JSR and labels for your subroutines because they will all be in the same file (separated by nice descriptive comment blocks). • However, the data will be in a separate file. You will need to figure out the address of where labels will fall when the file is loaded. • LD R0, Q2; load Q2 addr ;do something with address ...Q2 .FILL x3359

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